Cohesive forces prevent the rotational breakup of rubble-pile asteroid (29075) 1950 DA

Space missions and ground-based observations have shown that some asteroids are loose collections of rubble rather than solid bodies. The physical behaviour of such ‘rubble-pile’ asteroids has been traditionally described using only gravitational and frictional forces within a granular material. Cohesive forces in the form of small van der Waals forces between constituent grains have recently been predicted to be important for small rubble piles (ten kilometres across or less), and could potentially explain fast rotation rates in the small-asteroid population. The strongest evidence so far has come from an analysis of the rotational breakup of the main-belt comet P/2013 R3 (ref. 7), although that was indirect and poorly constrained by observations. Here we report that the kilometre-sized asteroid (29075) 1950 DA (ref. 8) is a rubble pile that is rotating faster than is allowed by gravity and friction. We find that cohesive forces are required to prevent surface mass shedding and structural failure, and that the strengths of the forces are comparable to, though somewhat less than, the forces found between the grains of lunar regolith.

[1]  A. Wesselink Heat conductivity and nature of the lunar surface material , 1948 .

[2]  J. K. Mitchell,et al.  Apollo soil mechanics experiment S-200 , 1974 .

[3]  T. Ahrens,et al.  Deflection and fragmentation of near-Earth asteroids , 1992, Nature.

[4]  D. Scheeres,et al.  Exterior gravitation of a polyhedron derived and compared with harmonic and mascon gravitation representations of asteroid 4769 Castalia , 1996 .

[5]  Petr Pravec,et al.  Fast and Slow Rotation of Asteroids , 2000 .

[6]  E. al.,et al.  Thermal infrared observations of the Hayabusa spacecraft target asteroid 25143 Itokawa , 2005, astro-ph/0509434.

[7]  Richard P. Binzel,et al.  Constraining near-Earth object albedos using near-infrared spectroscopy , 2005 .

[8]  William F. Bottke,et al.  THE YARKOVSKY AND YORP EFFECTS: Implications for Asteroid Dynamics , 2006 .

[9]  J. Kawaguchi,et al.  The Rubble-Pile Asteroid Itokawa as Observed by Hayabusa , 2006, Science.

[10]  K. Holsapple Spin limits of Solar System bodies: From the small fast-rotators to 2003 EL61 , 2007 .

[11]  Daniel J. Scheeres,et al.  Physical modeling of near-Earth Asteroid (29075) 1950 DA , 2007 .

[12]  A. Nakamura,et al.  Size-frequency statistics of boulders on global surface of asteroid 25143 Itokawa , 2008 .

[13]  S. N. Milam,et al.  The impact and recovery of asteroid 2008 TC3 , 2009, Nature.

[14]  Martin G. Cohen,et al.  THE WIDE-FIELD INFRARED SURVEY EXPLORER (WISE): MISSION DESCRIPTION AND INITIAL ON-ORBIT PERFORMANCE , 2010, 1008.0031.

[15]  D. Scheeres,et al.  Scaling forces to asteroid surfaces: The role of cohesion , 2010, 1002.2478.

[16]  S. Debei,et al.  Images of Asteroid 21 Lutetia: A Remnant Planetesimal from the Early Solar System , 2011, Science.

[17]  E. L. Wright,et al.  NEOWISE OBSERVATIONS OF NEAR-EARTH OBJECTS: PRELIMINARY RESULTS , 2011, 1109.6400.

[18]  S. Green,et al.  Directional characteristics of thermal–infrared beaming from atmosphereless planetary surfaces – a new thermophysical model , 2011, 1211.1844.

[19]  F. Spoto,et al.  Near Earth Asteroids with measurable Yarkovsky effect , 2012, 1212.4812.

[20]  The influence of rough surface thermal-infrared beaming on the Yarkovsky and YORP effects , 2012, 1203.1464.

[21]  P. Michel,et al.  Spin-up of rubble-pile asteroids: Disruption, satellite formation, and equilibrium shapes , 2012 .

[22]  C. Nugent Solar Radiation and Near-Earth Asteroids: Thermophysical Modeling and New Measurements of the Yarkovsky Effect , 2013 .

[23]  W. Losert,et al.  Simulating regoliths in microgravity , 2013, 1306.1764.

[24]  Daniel J. Scheeres,et al.  The strength of regolith and rubble pile asteroids , 2013, 1306.1622.

[25]  S. Green,et al.  A thermophysical analysis of the (1862) Apollo Yarkovsky and YORP effects , 2013, 1305.3109.

[26]  D. Vokrouhlický,et al.  Orbit and bulk density of the OSIRIS-REx target Asteroid (101955) Bennu , 2014, 1402.5573.

[27]  P. Michel,et al.  Thermal fatigue as the origin of regolith on small asteroids , 2014, Nature.

[28]  D. Farnocchia,et al.  Assessment of the 2880 impact threat from Asteroid (29075) 1950 DA , 2013, 1310.0861.

[29]  D. Scheeres,et al.  CONSTRAINTS ON THE PHYSICAL PROPERTIES OF MAIN BELT COMET P/2013 R3 FROM ITS BREAKUP EVENT , 2014, 1406.0804.

[30]  D. Lauretta,et al.  Thermal infrared observations and thermophysical characterization of OSIRIS-REx target asteroid (101955) Bennu , 2014 .